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Comparison of the clay mineralogy of the early Pleistocene paleosols With modern loess-derived soils

Document Type : Analytical and Applicable Papers

Authors

Dept. of Soil Science, Gorgan University of Agricultural Sciences and Natural Resources

Abstract

Introduction Loess sediments of northern Iran represent several cycles of climate change and evolution of the landform for the mid-to-late Quaternary. Climate change in elevations of Iran and its surrounding areas is very controversial in the mid and late Quaternary, and has been discussed in the past according to rainfall and rainfall periods and between rainfall, glacial and inter-glacial. Paleomegnatic results also indicate that these sediments have accumulated between, 1.8 to 2.4 million years ago. However, pedogenic processes and the effects of past climate in these soils still have not been fully investigated. The loess deposits in northern Iran are a valuable archive of regional paleoclimatic and paleoenvironmental information. Extensive sedimentological and chronological studies have been carried out on the middle to upper Pleistocene loess during the past decades, but it is necessary to do a comparative research on the older loess deposits. So, this study aimed to conduct a mineralogical and physicochemical investigation on the early Pleistocene loess and to compare it with modern loess soils in Agh-Band, Yelli-Badrag and Qareh-Agach in loess plateau of eastern Golestan.
Materials and Methods The study area is located in a hot and dry climate in loess Plateau east Golestan. According to the previous studies, a total of six profiles were excavated and studied. Then, physicochemical properties such as soil texture, acidity (pH), electrical conductivity (EC), saturation moisture (SP), organic carbon (OM), cationic exchange capacity (CEC) and calcium carbonate equivalent (CCE) were measured in the laboratory. Clay separation was carried out with a specific method to separate the clay as well as identification of clay minerals.  After preliminary field observations and determining the horizons for each profile in the region, soil classification was done based on soil taxonomy and WRB. Then, soil samples were prepared from each horizon for physicochemical and mineralogical studies in sufficient quantities.
Results and Discussion Comparing the results of physicochemical properties (such as color, lime percentage, the cation exchange capacity and the ratio of iron, etc.) in paleosol and modern loess soils indicates that in paleosol soils, soil forming processes have passed several stages. Clay mineralogy is a good indicator for past climate change studies in loess.The existence of the arglic horizons and the evolved calcic in paleosols and their absence, in comparison with the modern soils in which they are present, indicate the change in soil formation conditions. The change in the color of paleosols also represents the soil moisture and the more suitable conditions of the past climate (temperature, and especially rainfall) in comparison with the present climate of the region, this color change was due to activation of soil formation processes in paleosols. All paleosol samples had a higher clay content than the late modern loess soils of the Pleistocene, suggesting favorable climatic conditions for soil formation processes and the development of more ancient soil than parent materials. Decrease in the amount of annual precipitation in the region, compared to the past, has led to decreased smectit and increased chlorite. Therefore, presence of smectit cannot be attributed to the present situation of the region. The presence of these clay minerals in paleosols can be due to wet weather conditions as well as weathering of clay mineral deposits.  On the other hand, the dominance of less weathered clay minerals such as illite and chlorite in the late Pleistocene modern loess soils is correlated with the present dry climatic conditions.
Conclusion The simultaneous presence of modern and old loess soils in the studied areas demonstrates the general evolution of geographical and climatic conditions during the Pleistocene period which has altered the properties of these layers and ultimately left out the effects of high clay conditions, which is a combination of climatic evidence and intermittent pedogenic soil formation processes. The presence of early Pleistocene loess soils between late Pleistocene loess sediments in Golestan province and the conditions of the study provided pedological and mineralogical comparisons of modern and paleosols in these areas and the results clarified a part of the climate change in northern Iran. The past climate study allows for prediction of the current and future climate change process.  Therefore, a more accurate study of clay minerals as the key to all soil behaviors and past climate change in different parts of the eastern Golestan plateau can be very useful in completing studies of evidence of past climate change in paleosol soils

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References
  1. Almasi, A., Pashaei, A., Jalalian, A., and Ayoubi, S. 2004. Investigation on composition and volution of minerals in the loess deposits and plaeosols of Ghapanarea,Golestan Province, Journal of Agricultural Sciences and Natural Resources, 3: 10-20. (In Persian)
  2. Ayoubi, S., Jalalian, A., Eghbal, M.K., and Khademi, H. 2002. Identification and genesis of clay mineral in two paleosol from sepahanshahr (Isfahan) and EmamGheis (Charmahal-Bakhtiari). Iranian Journal of Crystalography and Mineralogy, 10: 157-178.
  3. Bech, J., Rustullet, J., Garrigo, F.J., and Tobias, R. 1997. The iron of some red Mediterranean soils from northeast spain and its pedogenicsighnificance. Catena, 28: 211-229.
  4. Birkeland, P.W. 1984. Soils and Geomorphology. Oxford University Press, New York.
  5. Bouyoucos, G. J. 1962. Hydrometer method improved for making particle size analysis of soils. Agronomy Journal, 54: 464-465.
  6. Blum H.P., Schwertman U., Genetic evaluation of profile distribution of Al, Fe and Mn oxides. 1969. Soil Soil Science Society of America, Proceedings, 33: 438-44.
  7. Chapman, H.D. 1965. Cation exchange capacity. In: Black, C.A. (Ed.), Methods of Soil Analysis. Part 2: Chemical and Microbiological Properties. Soil Science Society of America and American Society of Agronomy, Madison, WI, USA, pp: 891-901.
  8. Fanning D.S., Keramidas V.S., El-Desoky M.A. 1989. Micas. In: Dixon, J.B., Weed, S.B. 1989, Minerals in Soil Environments, 2nd ed., Soil Science Society of America.
  9. Gunal, H., and Ransom, M. D. 2006, b. Genesis and micromorphology of loess-derived soils from central Kansas. Catena, 65: 222-236.
    1. Jacobs, P.M., and Mason, J.A. 2004. Paleopedology of soils in thick Holocene loess, Nebraska, USA. Revista Mexicana de Ciencias Geológicas, 21: 54-70.
    2. Johns, W.D., Grim, R.E., and Bradley, W.F. 1954. Quantitative estimation of clay minerals by diffraction methods. Journal of Sedimentary Petrology, 24: 242-251.
    3. Kaviani, N., Khormali, F., Masihabadi, H., and Tazikeh, H. 2014. Micromorphology and clay mineralogy of loess-derived soils of natural and cultivated land uses along a climosequence in Golestan Province.  Journal of Water and Soil Conservation, 21(2): 31-58.
    4. Khormali, F., and Abtahi, A. 2003. Origin and distribution of clay minerals in calcareous arid and semi-arid soils of Fars Province, southern Iran. Clay Minerals, 38: 511-527.
    5. Khormali. F., Kehl M. 2011. Micromorphology and development of loess-derivedsurface and buried soils along a precipitation gradient in Northern Iran, Quaternary International, 123- 234: 109.
    6. Kiani, F., Jalalian, A., Pashaee, A., and Khademi, H. 2006. Clay minerals in soil-loess sequences in asang area, Golestan province. Iranian Journal of Crystalography and Mineralogy, 2: 395-412.
    7. Kittrick, J.A., and Hope, E.W. 1963. A procedure for particle size separation of soils for X-ray diffraction analysis. Soil Science, 96: 312-325.
    8. Mahaney, W.C., Hancock, R.G.V., and Sanmugadas, K. 1991. Extractable Fe-Al and geochemistry of late Pleistocene Paleosol in the Dalijia Shan, Western China. Journal of Southeast Asian Earth Sciences, 6: 75-82.
    9. Mckeague, J.A., and Day, J.H. 1966. Dithionite and oxalate extractable Fe and Al as aids in ifferentiating various classes of soil. Canadian Journal of Soil Science, 46: 13-22.
    10. McLean, E.O. 1982. Soil pH and lime requirement. In: Page, A.L. (Ed.): Methods of soil analysis. Part 2: Chemical and microbiological properties. Soil Science Society of America and American Society of Agronomy, Madison, WI, USA, pp: 199-224.
    11. Muhs, D.R. 2013. The geologic records of dust in the Quaternary. Aeolian Research, 9: 3-48.
    12. Mulders, M.A. 1987. Remote sensing in soil science, Agriculture University of Wageningen, Elsevier Publication, 9:3-48.
    13. Najafinia, M., Khormali, F., Kiani, F., Baranimotlagh, M. 2017. Comparison of the clay micromorphology of the early Pleistocene paleosols with modern loess-derived soils. International Conference on Loess Research, pp: 80.
    14. Nelson, R.E. 1982. Carbonate and gypsum. In: Methods of Soil Analysis. Part II. Page, A.L. (Ed.). American Society of Agronomy, Madison, Wisconsin, USA, 181-197.
    15. Nelson, D. W., and Sommers, L. E. 1982. Total carbon, organic carbon, and organic matter, In: Buxton, D.R. (Ed.), Methods of Soil Analysis. Part 2: Chemical and Microbiological Properties. SSSA, Madison,WI, USA. pp: 539-579.
    16. Page, M.C., Sparks, D. L., Noll, M.R., and Hendricks, G.J. 1987. Kinetics and mechanisms of potassium release from sandy Middle Atlantic Coastal Plain soils. Soil Science Society of America, 51: 1460-1465.
    17. Pashaei, A. 1997. Study of physico-chemical characteristics and the source of loess deposits in Gorgan plain region. Iranian Journal of Earth Sciences, 23-24: 67-68.
    18. Schaetzl, R.J., and Anderson, S. 2005. Soils: Genesis and Geomorphology. Cambridge University Press, 833p.
    19. Taheri, M., Khormali, F., Wang, X., Amini, A., Wei, H., Kehl, M., Frechen, M., Chen, F. 2017. Micromorphology of the lower Pleistocene loess in the Iranian Loess Plateau and its paleoclimatic implications. Quaternary International, 429: 31-40.
    20. Wang, X., Wei, H., Khormali, F., Taheri, M., Kehl, M., Frechen, M., Lauer, M., Chen, M. 2017. Grain-size distribution of Pleistocene loess deposits in northern Iran and its palaeoclimatic implications. Quaternary International, 429: 41-51.
    21. Wang, X., Wei, H., Taheri, M., Khormali, F., Danukalova. G., Chen, F. 2016. Early Pleistocene climate in western arid central Asia inferred from loess-palaeosol sequences. Scientific Reports, 1-9.
    22. Wilson M.J. 1999. The origin and formation of clay minerals in soils: past, present and 642 future perspectives. Clay Minerals, 34: 7-24.
    23. Ziyaee, A., Pashaei, A., Khormali, F., and Roshani, M.R. 2013.  Some physico-chemical, clay mineralogical and micromorphological characteristics of loess-paleosols sequences indicators of climate change in south of Gorgan. Journal of Water and Soil Conservation, 20(1): 1-27.

 

Agricultural Engineering
Volume 41, Issue 1
June 2018
Pages 127-141
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